Seminar Report For GPS Technology

1. Three Segments of the Global Positioning System
The Global Positioning System is comprised of three segments: the Control Segment, Space
Segment and User Segment.
Control Segment
The Master Control Station, or MCS (also known as the Consolidated Satellite Operations
Center) is located at the US Air Force Space Command Center at Schriever Air Force Base (formerly
Falcon AFB) in Colorado Springs, Colorado. The MCS responsible for satellite control and overall system
operations. The Control segment is made up of a Master Control Station (MCS), four monitor stations,
and three ground antennas (plus a reserve antenna at Cape Canaveral used primarily for pre-launch
satellite testing) used to uplink data to the satellites. Monitor Stations continuously receive GPS satellite
transmissions, and relay this information in real time to the Master Control Station in Colorado. The user
segment also receives these same transmissions.
Monitor stations (MS) are located at Schriever Air Force Base, Hawaii, Kwajalein Atoll, and Diego Garcia,
and Ascension islands. These stations are unmanned remote sensors that passively collect raw satellite
signal data and re-transmit it in real time to the MCS for evaluation. Monitor stations basically function
as very precise radio receivers, tracking each satellite as it comes into sky view. Ground antennas are
remotely controlled by the MCS. They are also located at Ascension, Diego Garcia, Kwajalein Atoll, as
well as Cape Canaveral, Florida. Ground antennas transmit data and commands from the Master Control
Station to GPS satellites. The MCS uplinks data to GPS satellites, which includes:
-Clock-correction factors for each satellite; necessary to insure that all satellites are operating at
the same precise time (known as “GPS Time”).
-Atmospheric data (to help correct most of the distortion caused by the GPS satellite signals
passing through the ionosphere layer of the atmosphere).
-Almanac, which is a log of all GPS satellite positions and health, and allows a GPS receiver to
identify which satellites are in its hemisphere, and at what times. An almanac is like a schedule telling a
GPS receiver when and where satellites will be overhead. Transmitted continuously by all satellites, the
almanac allows GPS receivers to choose the best satellite signals to use to determine position. The
almanac is automatically downloaded from satellites whenever a receiver is collecting a GPS signal. An
almanac can also be downloaded from a computer, a base station or other archived almanac.
-Ephemeris data is unique to each satellite, and provides highly accurate satellite position (orbit)
information for that GPS satellite alone. It does not include information about the GPS constellation as a
whole. Ephemeris information is also transmitted as a part of each satellite’s time signal.
By using the information from the GPS satellite constellation almanac in conjunction with the
ephemeris data from each satellite, the position of a GPS satellite can be very precisely determined for a
given time.

2. Space Segment
The Space Segment is an earth-orbiting constellation of 24 active and five spare GPS satellites
circling the earth in six orbital planes. Each satellite is oriented at an angle of 55 degrees to the equator.
The nominal circular orbit is 20,200-kilometer (10,900 nautical miles) altitude. Each satellite completes
one earth orbit every twelve hours (two orbits every 24 hours). That's an orbital speed of about 1.8
miles per second, and each satellite travels from horizon to horizon in about 2 hours.
Each satellite has a design life of approximately 10 years, weighs about 2,000 pounds, and is
approximately 17 feet across with its solar panels extended. Older satellites (designated Block II/IIA) still
functioning are equipped with 2 cesium, and 2 rubidium atomic clocks. Newer satellites (Block IIR) are
equipped with rubidium atomic clocks. All satellites also contain 3 nickel-cadmium batteries for backup
power when a satellite is in earth eclipse (out of view of the sun).
Each satellite transmits as part of its signal to ground stations and GPS receivers the following
information:
-Coded ranging signals (radio transmission time signals that allow a GPS receiver to triangulate
its position).
-Ephemeris position information (a message transmitted every 30 seconds containing precise
information on the location of the satellite in space).
-Atmospheric data (information to help correct interference of the signal as it travels through
the earth’s atmosphere).
-Clock correction information defining the precise time of satellite signal transmission (in GPS
Time), and a correction parameter to convert GPS Time to Universal Coordinated Time (UTC).
-An almanac containing information on the GPS constellation, which includes location and
health of all the satellites. Whenever a GPS receiver is receiving a satellite signal it is automatically
downloading an almanac. This almanac is stored in the receiver’s memory for future use. The stored
almanac allows a receiver to more quickly acquire GPS satellite signals because it already knows the
general location, and other information, about the satellites in the constellation. However, if a GPS
receiver is left turned off for several months, or is moved more than 300 miles while turned off, the
stored almanac may not be of any use to the receiver when it is turned on. A new almanac will be need
to be downloaded for the receiver to function properly.
The Four Basic Functions of the GPS
The primary functions of the GPS fall into four categories:
1) Position and waypoint coordinates: A GPS receiver can provide position or waypoint
information for its current location or any remote location on earth, and display that information in a
variety of coordinates.

3. 2) The distance and direction between a receiver’s position and a stored waypoint, or between
two remote waypoints.
3) Velocity reports: Real time distance to any waypoint; tracking to a waypoint; heading
(direction of travel); current speed; estimated time of arrival to a waypoint, course over ground, etc.
4) Accurate time measurement: GPS has become the universal timepiece, allowing any two
receiver clocks (as well as any two clocks or watches) to be precisely synchronized anywhere in the
world. The Global Positioning System operates using “GPS Time,” which varies slightly from Universal
Coordinated Time (UTC). A GPS receiver corrects GPS Time anomaly to match UTC time (also known as
“Zulu Time” or “Greenwich Time”), which is then offset by local time zone entered into the receiver by
the user.
How a Receiver Determines Its Position
Traveling at the speed of light, each satellite PRN signal takes a brief, but measurable amount of
time to reach a GPS receiver. The difference between when the signal is sent and the time it is received,
multiplied by the speed of light, enables a GPS receiver to accurately calculate the distance between it
and each satellite, provided that several factors are met.
Those factors are:
Good satellite signal lock by the GPS receiver (already covered)
A minimum of four satellite signals (discussed next)
Good satellite geometry (discussed later)
When a GPS receiver is turned on it immediately begins searching the sky for satellite signals. If
the receiver already has a current almanac (such as one acquired on a previous outing), it speeds up the
process of locating the first satellite signal. Eventually it locates and acquires its first signal. Reading this
signal the receiver collects the Navigation Message. If the receiver does not have a current almanac, it
must collect a new almanac, which will take about 12-13 minutes after the first satellite signal is
acquired. The almanac is automatically updated during normal use.
In the above graphic, the GPS receiver has calculated a rough location that places it somewhere
on the three dimensional sphere, which is actually thousands of miles in diameter. All the receiver can
really do at this point is collect system data and search for more satellite signals.
How a Receiver Determines Its Position (cont.)
For most receivers three satellites can only provide a two-dimensional (2D) position. Without
manually entering the receiver’s exact elevation (most GPS receivers don’t allow elevation to be entered
manually), the rendered 2D position may be off by several kilometers on the ground. If the exact
elevation of the GPS receiver is known, entering that elevation into a receiver with this capability
replaces the need for a fourth satellite signal to allow a receiver to triangulate a precise position. The

4. receiver essentially uses elevation in lieu of a fourth satellite, and makes the appropriate adjustments to
trilaterate a reasonably good 3D position.
But without manual elevation correction most GPS receivers must rely on a fourth satellite to
provide the final clock correction information necessary to calculate a 3D position. Until a fourth
satellite signal is acquired the receiver will not be able to determine x and y horizontal, and z vertical
positioning (a true 3D position). This is because the fourth satellite signal is used by the receiver not to
provide more position data, but, rather, the final time correction factor in its ranging calculations.
As a rule, 2D positions should always be avoided whenever possible. Use 2D positioning only
when a 3D position is not possible, but be aware of the horizontal error inherent in any 2D position. The
inability of a GPS receiver to triangulate a 3D position may be due to a variety of factors, including user
error, poor satellite geometry, and harsh landscape conditions (tall buildings, canyons, and dense tree
cover among others). As will be shown later in the course, all GPS receivers provide some means for
informing the user which mode they are operating in. It’s up to the user to be aware of the errors
associated with 2D positioning.
How a receiver determines its position (cont.)
For a GPS receiver to achieve three-dimensional (3D) positioning it needs to acquire four or
more satellite signals. A 3D position is comprised of X and Y (horizontal), Z (vertical) positions, and
precise time (not varying more than a few hundred nanoseconds). The receiver’s processor uses the
fourth satellite pseudo-range as a timing cross check to estimate the discrepancy in its own ranging
measurements and calculate the amount of time offset needed to bring its own clock in line with GPS
Time (recall the radio station and record player simultaneously playing the same song). Since any offset
from GPS Time will affect all its measurements, the receiver uses a few simple algebraic calculations to
come up with a single correction factor that it can add or subtract from all its timing measurements that
will cause all the satellite spheres to intersect at a single point (x, y, and z).
That time correction synchronizes the receiver's clock with GPS Time. Now the receiver
essentially has atomic clock accuracy with the time correction factor needed to achieve precise 3D
positioning. The pseudo-ranges calculated by the GPS receiver will correspond to the four pseudo-range
spheres surrounding the satellites, causing the four spheres to intersect at precisely the receiver’s
location (the dot in the diagram).
Selective Availability (Anti-Spoofing)
Selective Availability (S/A) was the intentional degradation (referred to as “dithering”) of the
Standard Positioning Service (SPS) signals by a time varying bias. Selective Availability is controlled by
the Department of Defense to limit accuracy for non U. S. military and approved users. The potential
accuracy of the coarse acquisition (C/A) code at around 30 meters was reduced by Selective Availability
up to 100 meters. In May, 2000, the Pentagon set Selective Availability to zero. The Pentagon did not
turn S/A off, but rather merely reduced the amount of signal dithering to zero meters, effectively
eliminating intentional position errors for Standard Positioning Service users.

5. Sources of Signal Interference (cont.)
Selective Availability (see previous slide).
Control Segment blunders due to computer glitches or human error can cause position errors from
several meters to hundreds of kilometers. Checks and balances by the Air Force Space Command
virtually eliminates any blunders in the Control and Space segments of the Global Positioning System.
User mistakes account for most GPS errors on the ground. Incorrect datum and typographic errors
when inputting coordinates into a GPS receiver can result in errors up to many kilometers. Unknowingly
relying on a 2D position instead of a 3D position can also result in substantial errors on the ground. A
GPS receiver has no way to identify and correct user mistakes.
Even the human body can cause signal interference. Holding a GPS receiver close to the body can block
some satellite signals and hinder accurate positioning. If a GPS receiver must be hand held without
benefit of an external antenna, facing to the south can help to alleviate signal blockage caused by the
body because the majority of GPS satellites are oriented more in the earth's southern hemisphere.
Errors in GPS are cumulative, and are compounded by position dilution of precision (PDOP) (covered
later). It is the user’s responsibility to insure the accuracy of the data being collected with the GPS.
Ideal Satellite Geometry
Satellite geometry refers to the positions of satellites relative to each other in space. Dilution of
Precision (DOP) is an indicator of the quality of a GPS receiver’s triangulated position relative to the
quality of the geometric positions of the satellites whose signals the receiver is using. GPS receivers get
satellite position information from the ephemeris message sent as part of the data stream from each
satellite.
Dilution of precision uses numerical values to represent the quality of satellite geometry, from 1
to over 100. The lower the number, the better the accuracy of position fixes. Some high-end GPS
receivers (such as Trimble data loggers) have a default PDOP setting of around 8, and the value can be
changed to meet the needs of the user. Garmin receivers do not allow PDOP manipulation by the user,
nor do they provide a PDOP value. Instead they use estimated position error (EPE) value in feet or
meters, which provides an estimate of the amount of horizontal error caused by poor satellite
geometry.
The outer ring of the circle in the above diagram represents the earth’s horizon. The center of
the cross hair represents the sky directly above the GPS receiver. The satellite configuration shown is
considered optimal for providing the best 3D positioning because any horizontal error from one

6. direction will be offset by the opposing satellites. The fourth satellite directly overhead improves vertical
accuracy.
Poor Satellite Geometry
(Note: To properly view the animation in this diagram, use Slide Show feature of PowerPoint.)
The locations of satellites in relation to each other in space at any given time can affect the
quality of a GPS receiver’s position fix. Spaced low on the horizon, with no satellite directly above the
receiver, can result in high PDOP. Similarly, if all satellites acquired by a receiver are bunched closely
together in one quadrant of the sky can also result in poor triangulation measurements (and a high
PDOP). Topography on the ground also affects satellite geometry. A receiver inside a vehicle, near tall
buildings, under dense canopy, or in mountainous terrain can be affected by blocked signals. GPS
receivers require clear line of sight to every satellite being acquired.
The above diagram is a PowerPoint animation. Each part of the animation corresponds to the
following sets:
Satellite set 1: This satellite configuration results in poor PDOP and HDOP, but good VDOP. This is an
example of a poor satellite configuration for achieving a precise position.
Satellite set 2: This satellite configuration represents poor PDOP and VDOP, but good HDOP. It’s
important to remember that satellite geometry that is poor for one kind of DOP can actually reduce
another kind of DOP. If you need the best horizontal measurements, but don’t care about vertical
accuracy, then this example is an acceptable satellite configuration.
Satellite set 3: This satellite configuration represents poor PDOP, VDOP, and HDOP. This is another
example of a poor satellite configuration.
How Good is WAAS?
The Wide Area Augmentation System (WAAS) dramatically improves existing GPS technology for
positional accuracy (in the United States and portions of Canada and Mexico). Under ideal conditions,
with Selective Availability set to zero, horizontal accuracy with GPS can be fifteen meters or less. Under
the same conditions with good WAAS signal acquisition that horizontal accuracy can be reduced to as
low as three meters or less on the ground.
Bear in mind that many factors dictate the level of accuracy that can be achieved by any GPS
receiver on the ground. Among these factors include errors in the GPS, multipath interference,
atmospheric errors, closed canopy or other signal blockers, and human error. Combined, these errors
can degrade positional accuracy to 100 meters or more. For WAAS, two downsides are its reduced
capability under heavy canopy (trees, canyons, etc.), and its limitation to mostly the contiguous U.S. In
fact, some studies have shown that WAAS signals are degraded the further north from the 35 parallel
one goes, reducing WAAS reliability in northern latitudes.